WO2014020270A1

WO2014020270A1 - High-strength grid with reinforced bonding for buried networks or devices

Info

Publication number: WO2014020270A1
Application number: PCT/FR2013/051820
Authority: WO
Inventors: Jean-Paul Ducol; Jacques Tankere; Bastien DUPUIS; Germain Auray
Original assignee: Mdb Texinov; Deltaval
Priority date: 2012-08-01
Filing date: 2013-07-29
Publication date: 2014-02-06
Also published as: PL2880211T3; EP2880211B1; RU2639068C2; FR2994200A1; ES2569117T3; FR2994200B1; RU2015101889A; EP2880211A1

Abstract

This high-strength geotextile grid comprises reinforcement fibres combined into parallel cords forming strips (101,103,105) oriented in at least two directions, said strips being separated by minimum intervals of 1 millimetre, said strips having homogeneous or different widths extending between 1 and 20 centimetres. Furthermore, strips having large widths (106) greater than 6 centimetres are provided at least on the edges of the grid.

Description

HIGH-RESISTANCE GRID WITH REINFORCED CONNECTION FOR NETWORKS OR DEVICES

BURIED

TECHNICAL AREA

The present invention relates to a geotextile grid, coated or not, reinforced with different fibers, the combination of these fibers together being achieved by means of a particular binding. This geotextile grid is intended to be implemented for protection applications of underground networks or devices during civil engineering works.

The conservation of the integrity of the grid also makes it possible to give it an essential warning role for the operators involved in said civil engineering works.

The grid comprises at least one series of parallel strands or reinforcing cables forming strips. This grid can also receive a coating, for example in the aqueous phase, as part of an eco-design approach, with bright color determined to optimize its warning power. It can benefit from marking to reinforce the alarm function. This grid can also integrate sensors or systems relating to the auscultation and monitoring of structures (optical fibers, reflector georadar type aluminum strip, etc ...) Among the civil engineering applications likely to implement the grid of the present invention, pipeline protections can contain different types of liquid (water, oil etc.) or different gas (natural gas, oxygen, hydrogen etc.). The grid can also be used to protect cables and / or fibers buried in the ground or any type of structure buried in the ground (formwork ...).

The grid can also be used for other mining type protection applications for example.

The main purpose of the grid is to create a barrier of sufficient mechanical resistance capable of warning operators of the nature of the buried network or device as well as of the potential danger. It can also integrate sensors or actuators to facilitate investigations around the future buried network (optical fiber, temperature or humidity sensor, heating resistor ...). PRIOR STATE OF THE ART

In the field of civil engineering, there are protective plates and warning grilles. In addition, perforated plates are commonly used to perform the protective functions of a network, including infrastructure and networks subjected to stresses due to mechanical aggression by a third party, such as for example resulting from the activation of a shovel or backhoe on a pipeline-overpipe system). Such plates are generally made of HDPE (high density polyethylene) and provide complete mechanical protection against aggression. They do not rise to the surface in case of aggression, nor play the role of a warning mesh. They are usually linked together in this system to ensure continuity of protection. These plates are for example described in the document WO 2012/004500.

Warning or signaling grids are also commonly used during earthworks around the grids. Their strong visual warning makes you stop working to avoid an incident.

Such warning or signaling grids are generally made of polyethylene, PVC or polyolefins and have a low mechanical strength and a high capacity for deformation. Their color is related to the conventional rules concerning the work of buried networks, thus allowing an identification of the nature of the network located below. They are sometimes also associated with a marking indicating the type of network concerned. This deformability and color gives them the ability to emerge from the ground, and to be used as signaling a danger. There are also geoland reinforcement, whose mechanical strength has been studied to take the efforts and deformations and stabilize earthworks. These grids have a limited cohesion, the bonding between the fibers not being solicited in operation The geo-reinforcing grids are generally made of high tenacity fibers such as PET (polyethylene terephthalate), glass, aramid, polypropylene , etc. and can be coated (acrylic, PVC or other) or associated with other materials (non-woven, woven, spacer, resins, dies). These geo-grids can integrate measurement sensors, for example stress, deformation or temperature, which may be in the form of optical fibers. WO 2005/103606 describes an example of such systems. These grids are subject to the rules of the art and building codes, and must ensure the longevity and safety of the structures thus composed. In particular, the quality of the grids must allow to preserve a maximum of mechanical properties during aggressive episodes on the structure, either during construction (damage to the implementation ...), or later during the life of the structure (creep, infiltration, surrounding chemical environment ...).

The expected properties of the various protection solutions are better explained in the following way:

• the plate located above or on the side of the structure to be protected must be able to maintain its integrity during an aggression episode above the structure (construction shovel, for example). A material having a good resistance with a low level of deformation can advantageously provide this function. During the mechanical aggression, the product must be able to block the progression of the excavator. Continuity of protection must be ensured by connecting the plates together.

• The warning mesh must be colored and deformable enough to be able to be raised to the surface and to provide its warning function.

• The geo-grid plays a role of reinforcement to ensure the long-term stability of the structure and thus the safety of users. Apart from high strength capabilities, it is not designed to be a protection in case of aggression by excavation: it can be noted in particular the weakness of the links of the reinforcing elements between them.

These different solutions involve holes or through openings, necessary to allow the free flow of water in the soil.

Products made of conventional polymers must in fact often be oversized in terms of the amount of material to obtain acceptable deformation, sufficiently low in normal use. The current polymers with limited costs have too much elongation at low stress.

In order to improve the mechanical properties of the grid, a bi-module solution can be envisaged, as for example described in document WO 2010/007279. The bi-module solution provides a better response in the case of use in protection because it allows a blocking of the progression of the shovel more quickly at first, while having a deformation capacity able to bring out the grid of earth, in order to be able to warn in a second time, without the rupture of the grid intervenes.

The bi-module associates one or more reinforcing fibers having different mechanical properties. The fibers may be of mineral origin (glass, basalt, etc.), polymer (polyester, polypropylene, aramid, etc.), natural (flax, hemp, etc.). The bi-module allows to use:

• fibers with low elongation (elongation module under high tension) and with an elongation value of rupture of between 2 and 5%, and

Polymer type fibers and / or fibers of natural origin having a modulus of elongation under tension lower than that of the fibers with a small elongation, and a value of elongation of fracture significantly greater than that of said fibers with a small elongation, and between 10 and 20%.

The object of the present invention is to be able to combine the protection or reinforcement characteristics existing in the plates, the warning grids and the geo-grids, in order to arrive at a structure that is both sufficiently deformable and visible, while being resistant to attack and blocking the action resulting from construction machinery. SUMMARY OF THE INVENTION

The present invention thus relates to a grid of very high resistance, dual function of signaling and protection of all networks or devices buried or underwater.

It relates to a reinforced protection grid, comprising at least two sets of strands or reinforcing cords, parallel to each other, forming strips oriented in at least two different directions. The fibers of the cords or strands may be of the same nature (polymer, aramid, mineral, or natural fiber) or of several materials. They can also integrate intelligent sensors or fibers for the auscultation of the system or the civil engineering work by systems such as optical fibers or reflectors georadar. According to a first aspect of the invention, the strips have homogeneous or different widths extending between 1 and 20 centimeters, bands of greater widths of more than 6 cm being formed on the edges of the grid. In addition, the strips oriented in the same direction are separated from each other by a distance of at least 15 millimeters.

In doing so, the grid is reinforced at this level against the localized aggressions at the edge of protection, and in addition, it is possible to carry out a much clearer marking with the aid of a printing ink, in order to ensure the function of signaling, for example the type of network that is intended to protect said grid.

This reinforcement, which makes the edge of the grid more resistant, is important because if the blind attacker in the ground touches only the edge of the grid, it is essential that it encounters a high resistance and raises the warning grille.

These larger width strips may result from the grid manufacturing technology. However, they can also be fixed to the grid after production by gluing or sewing. According to a second aspect of the present invention, the binding of the strands or cords constituting the parallel or perpendicular strips between them consists of specific armor, made using high tenacity yarns.

These yarns comprise or incorporate a high performance polymer in resistance and in modulus, the deformation at break is less than 6%. These yarns are, for example, chosen from the group comprising aramids, aromatic polyester (Vectran®), very high molecular weight polyethylene (Dyneema®), polyvinyl acetate (PVA), over-stretched polypropylene, high-density polyethylene, and glass-type mineral fibers. or basalt, possibly sheathed or composite.

This mode of connection provides cohesion between the bands in the different directions, thus allowing the transfer of forces and the tear resistance.

This type of product is made on a weaving loom with "no gauze" weave or Rachel loom. According to a third aspect of the invention, the wireline in cross-machine direction is not cut, but on the contrary remains continuous at the edge of width by turning the same son without interruption (similar to the technology of the weaving shuttle).

This type of product can be achieved by adapting Rachel type machine (marketed for example by the company Karl Mayer) or on a shuttle loom with a type of armor "no gauze". In this case, when it solicits the grid thus obtained, there is a necking effect in width, increasing the density of cords that absorb energy. The efforts are thus transferred to the warp cords, avoiding tearing.

In addition, the fibers of the cords constituting the strips may be of a homogeneous nature (high tenacity polymer, aramid, mineral fiber or natural origin) or of several different types (bi or multi module).

According to the invention, the fibers of the constituent cords of the strips are made of one or more combined materials, chosen from the group comprising:

The following polymers: polyester, polypropylene and polyethylene, aramid, PVA, aromatic polyesters;

• mineral fibers, including E glass, AR glass and S glass, and basalt, possibly sheathed or protected by a coating of acrylic, PVC or bituminous type;

· Fibers of natural origin, including hemp and flax.

The multi-component grid can be made on the looms usually used for the production of tablecloths (such as the DORNIER or SULZER looms). Dornier's 'Lino' technique of the 'no gauze' type can be used because it allows the introduction of an independent bonding wire reinforcing son

It is also possible to implement chain and Rachel technology on Karl Mayer or Liba-type looms for example, with or without insertion of frames. These technologies make it possible to work aramid, mineral fibers (glass or basalt), without altering the fiber, in particular mechanically, while producing complex structures and meshes including many other materials. Examples of armor are described in the detailed description of the figures. However, it can already be stated that the type of looming type Rachel framer or multiaxial chain type with sectional weft under two or more needles, or type two bars in opposition opposite two or more needles, or in armor atlas type with bars in opposition intervening on several columns of mesh or by variation of electronic program in sequence combining the bindings, and thus, introducing a stop mesh effecting "rib-stop" that is to say, blocking the mesh . This grid may be monodirectional, bidirectional or multidirectional, and may be associated with a nonwoven or possibly another type of support, such as a woven or multilayer. This additional layer thus simultaneously ensures the functions of protection, alarm, reinforcement, filtration and separation to perfectly stabilize the environment of the pipes, electrical cables or other equipment to protect.

The grid may also undergo a heat treatment, followed or not by a coating, able to adjust the rigidity of the product if necessary. This coating may be of acrylic, PVC or bituminous type.

Such a heat treatment possibly ensures a shrinkage of the bonding fibers at a suitable temperature. This shrinkage improves the clamping between them of the fibers of the different directions to optimize the transfer of forces. The coating makes it possible to protect the reinforcing and bonding fibers during the attack, for example a shovel or any other external attack, and contributes to the cohesion of the assembly.

The coating can be performed following the production of the grid (in line with the trade) or, in a second production step. The coating can be carried out on impregnation-drying type machines from Menzel or Ontec.

The grid is also marked with inscriptions informing of the nature of the danger, for example "Gas Pipeline", before or after the coating of the grid.

It may be noted that the marking made before coating makes it possible to protect the writing system within the coating and thus ensure its durability.

The alarm function is ensured by the color of the coating, adapted to the network to be treated and / or a marking on the product (message sticking, ink, printing ...). According to the invention, the adjacent or consecutive grid strips may be interconnected during any work on the structure. Thus, if the operator is required to cut the grid at a specific location of the structure to make repairs, it must be possible to connect it when finishing the work to preserve a continuous protection. Thanks to the geometry and the strong resistance of the bands, the grid offers spaces of 15 to 100 millimeters, allowing to introduce different forms of loops or straps to thus allow to connect two grids between them. Buckles made of galvanized metal, plastic, or stainless steel are inserted between the strips of each of the grids that must be bonded over a portion or the entire width of the product. These loops make it possible to tighten the bands when the grid is energized. These loops can be supplemented by a strap or rope to ensure a better diffusion of the forces inside the grid.

Thus, the connection between consecutive grid strips can be achieved at the bands in the production direction with the aid of such loops or belt-type system or rope on a part or over the entire width of the grid.

The protective grid has many advantages:

• a specific binding allowing a better transfer of the charges between the fibers put in frame and those put in chain.

• the implementation of wider fiber strips at the edges, to respond to local aggression at this level. These strips allow a suitable signaling marking.

• the colored coating of the product makes it possible to be able to warn during its ascent with a shovel or a construction machine. The coating may furthermore confer a greater or lesser rigidity on the product. The coating also makes it possible to reinforce and protect the connections between the reinforcing cables.

In the case of the bi or multi-module solution, a very high mechanical strength can be obtained with a small deformation in a first step with the first type of fibers, which leads to the blocking of the shovel or the machine of site faster. Then, in a second step, the deformation of the grid becomes possible in order to be able to reassemble the product so that it preserves its integrity and assures its role of alarm.

• the possibility of inserting smart fibers, such as optical fiber type sensors, georadar reflectors, conducting wires, electrical resistors, metal strips, etc., makes it possible to anticipate the monitoring and the auscultation of the networks .

• The specific construction with coating and strips allows a system of connection between the grid sheets to allow the transfer of forces, especially for identified local repairs of the grid. BRIEF DESCRIPTION OF THE FIGURES

The manner in which the invention can be realized and the advantages which result therefrom will emerge more clearly from the following exemplary embodiments, given as an indication and not a limitation to the accompanying figures.

Figure 1 schematically illustrates a grid view from above according to a first embodiment of the invention, Figure 2 is a sectional view. Figure 3 describes a grid of the invention with continuity of frames.

Figures 4, 5, 6 and 7 show different bonding structures of the son cables in the production sense and through.

FIG. 8 describes modes of connection between the bands of the successive grids during the possible repairs.

Figures 9 and 10 describe the modes of attack of the excavator on site

MODE OF CARRYING OUT THE INVENTION

FIG. 1 illustrates the production and arrangement of the cable strips in the production (chain) and in the cross direction (weft) directions.

In the production direction, the strips comprise the cords (101, 103, 105) in number calculated to obtain the necessary resistance to the grid. These can be of the same nature or have cables based son of different performance to achieve a bi or multi-module effect. The techniques of association of the cords or fibers on weaving machine son or Rachel loom are represented schematically by the binding son (102). described below.

The reference (104) represents the marking on a cable band. FIG. 2 is a diagrammatic sectional representation of FIG. 1, which makes it possible to distinguish this structure better from the warp and from the field direction cords with schematically the orthogonal connection thereof.

The binding yarns (made of aramid, high-tenacity polyester or bi-modulus) of reinforcing fibers (203) and weft threads (201) have been materialized by reference (202). Figure 3 depicts the example of a construction with continuous screening; in this case the reversal of the weft son (301) on the edges of the grid is without interruption. This embodiment is manufactured by adaptation of Rachel VS type machine Karl Mayer for example, or on loom with shuttle.

This figure 3 shows the cords (302), which are connected to the frames (301) by the binding structure embodied by the wires (303).

It is understood that in this case of construction, the fact of exerting traction in the production direction of the grid tends to create a necking in width due to the tightening of the frames in question.

The diagrams illustrated in FIGS. 4, 5 and 6 represent non-limiting examples of binding for securely associating the strands or cords with technical wires arranged in the direction of production and cross-machine direction.

Thus, in FIG. 4, it is an arrangement of chains (401) interconnected by partial frames (402), ensuring on the one hand the fixing of the cords (403) in the sense of the warp with the frames (404). ) transverse, and providing, on the other hand, a tear resistance of the grid in question.

FIGS. 5 and 6 correspond to two other types of bonding modes with more structuring thread sets to further reinforce the binding of the yarn cords and thus to oppose more strongly the risks of orthogonal tearing.

In FIG. 5, it is possible to observe the displacement in opposition of the wires (501) and the wires (502) so as to "tighten" as much as possible the cords of the two directions.

FIG. 6 illustrates an even more structuring mode of binding, of the "Atlas" type. This binding method has the advantages of moving the binding yarn on several columns of stitches, and consequently to better distribute the connection forces; what is desired for the specific application of this grid.

As mentioned above, these bindings act in combination with the quality and nature of the threads used, that is to say with the performance of the yarns, in particular high-tenacity polyester or aramid. The wires (401) and (402), (501) and (502), and (601) and (602) may be of the same or different nature to achieve the goal of excellent cable bonding.

Figure 7 illustrates a multi-component grid that can be performed on looms, such as looms DOR IER or SULZER. The "Lino" technique of Dornier can be used because it allows the introduction of binding threads (703) independent of the reinforcement threads (701) and (702).

FIGS. 8a and 8b illustrate the bonding of the adjacent grid strips during repairs on the structure by loop systems or mechanical links which allow the joining strength. The first reinforcing strip (802) and that of the second reinforcing strip (803) are passed through a steel loop (801), with the possibility of pulling on the latter to effectively connect the grids - object of the invention. FIG. 8b perfectly illustrates this very important junction for the application of the grid, this notion of junction being well known as constituting a weak point of the devices of the prior art.

It is also conceivable that the reinforcement strips located at the edges of the grid can themselves ensure the bonding between two adjacent grids. In this case, they are also connected with loops, of the type made of galvanized metal or other. It is thus possible to assemble said strips of each of the grids that must be bonded, over a portion or over the entire width of the grid, and this, directly on the site. These loops make it possible to tighten the bands when the grid is energized. It is observed that under these conditions, a large part of the efforts is retransmitted and thus brings a continuity of system performance.

Figures 9 and 10 show the attack of a construction shovel (901) on the grid (902) located above the structure (903). The shovel (901) must be blocked by the grid (902) so that it can not damage the structure. The blocking effect is even more pronounced in the case where a multi-module grid is used at the level of the reinforcing strips and in the binding fibers. When raising the grid (1002) after the action of the shovel (1001), said grid must be sufficiently deformable to maintain its integrity and keep its warning power.

Claims

High-strength geotextile grating comprising reinforcing fibers gathered in parallel cords (101, 103, 105) forming bands oriented in at least two directions,

• said strips being separated by minimum intervals of 15 millimeters,

Said strips having homogeneous or different widths extending between 1 and 20 centimeters,

bands of large widths (106), greater than 6 centimeters, being formed at least on the edges of the grid.

High strength geotextile grating according to claim 1, characterized in that the strips (106) of larger widths formed at the edge of the grid receive a marking (104).

High-strength geotextile grating according to one of Claims 1 and 2, characterized in that the connection between the strips of different directions is carried out with high-tenacity yarns (202, 303, 401, 402, 501, 502, 601, 602, 703) whose deformation at break is less than 6%.

High-strength geotextile grating according to one of Claims 1 to 3, characterized in that the frames (301) are not cut but instead remain continuous by turning around the edge of the width, so as to provide a cohesion between chains and frames and to ensure the transfer of efforts.

High strength geotextile grating according to one of claims 1 to 4, characterized in that it is carried out on a loom type Rachel framer or multiaxial, and in that the binding is of type chain with sectional weft under two or more needles , or of type two meshing bars in opposition under two or more needles, or in armor of atlas type with bars in opposition intervening on several columns of meshes or by variation of electronic program in sequence introducing a stop mesh effecting "rib-stop That is blocking the mesh

High-strength geotextile grating according to one of Claims 1 to 4, characterized in that it is carried out on a weaving machine. High-strength geotextile grating according to one of Claims 1 to 6, characterized in that it is monodirectional, bidirectional or multidirectional, and in that it receives by insertion a non-woven or woven web or a multilayer.

High-strength geotextile grating according to one of Claims 1 to 7, characterized in that the fibers of the constituent cords of the strips are of a homogeneous nature (high-tenacity polymer, aramid, mineral fiber or of natural origin) or of several different types (bi or multi module).

High strength geotextile grating according to one of Claims 1 to 8, characterized in that the reinforced bonding is made of high tenacity yarns selected from the group consisting of aramids, aromatic polyesters, very high molecular weight polyethylenes, polyvinyl acetate (PVA), super-stretched polypropylenes, high density polyethlene, and glass or basalt type mineral fibers, optionally sheathed or composite,

High strength geotextile grating according to one of Claims 1 to 9, characterized in that the fibers of the constituent cords of the strips are made of one or more combined materials, chosen from the group comprising:

• fibers of natural origin, including hemp and flax.

High strength geotextile grid according to one of claims 1 to 10, characterized in that it is coated with a coating of acrylic, PVC or bituminous type.

High-strength geotextile grating according to one of Claims 1 to 11, characterized in that intelligent specific fibers are integrated into its structure in order to allow the auscultation or monitoring of the structure or grid to be carried out. .

13. high strength geotextile grid according to claim 12, characterized in that the intelligent fibers are selected from the group comprising conductive son, optical fibers, electrical resistance, metal strips, reflectors georadar type aluminum strips.

14. high strength geotextile grid according to one of claims 1 to 13 characterized in that it is subjected to a heat treatment capable of ensuring the withdrawal of binding son, to strengthen the links between the bands oriented according to different directions.

High-strength geotextile grating according to one of Claims 1 to 14, characterized in that the connection between consecutive strips of grids is carried out at the level of the strips in the production direction using galvanized metal, plastic or stainless steel buckles. , or strap type system or rope on a part or the full width of the grid.